Protein sorting in yeast: the localization determinant of yeast vacuolar carboxypeptidase Y resides in the propeptide

We have isolated cis-acting mutations in the gene encoding the yeast vacuolar protein carboxypeptidase Y (CPY) that result in missorting and aberrant secretion of up to 95% of newly synthesized CPY. The CPY polypeptides synthesized by these mutants use the late secretory pathway to exit the cell, since the late-acting sec1 mutation prevents their secretion. The mutant versions of CPY are secreted as the proCPY zymogen and are enzymatically activatable in vivo and in vitro. All the mutations, including small deletions and an amino acid substitution, map to the amino-terminal propeptide region and define a discrete yeast vacuolar localization domain whose integrity is required for efficient sorting of the CPY zymogen. Thus, the N-terminal propeptide of CPY carries out at least three functions: it mediates translocation across the endoplasmic reticulum, renders the enzyme inactive during transit, and targets the molecule to the vacuole.     

Early stages in the yeast secretory pathway are required for transport of carboxypeptidase Y to the vacuole

Temperature-sensitive secretory mutants (sec) of S. cerevisiae have been used to evaluate the organelles and cellular functions involved in transport of the vacuolar glycoprotein, carboxypeptidase Y (CPY). Others have shown that CPY (61 kd) is synthesized as an inactive proenzyme (69 kd) that is matured by cleavage of an 8 kd amino-terminal propeptide. sec mutants that are blocked in either of two early stages in the secretory process and accumulate endoplasmic reticulum or Golgi bodies also accumulate precursor forms of CPY when cells are incubated at the nonpermissive temperature (37°C). These forms are converted to a proper size when cells are returned to a permissive temperature (25°C). Vacuoles isolated from sec mutant cells do not contain the proCPY produced at 37°C. These results suggest that vacuolar and secretory glycoproteins require the same cellular functions for transport from the endoplasmic reticulum and from the Golgi body. The Golgi body represents a branch point in the pathway: from this organelle, vacuolar proenzymes are transported to the vacuole for proteolytic processing and secretory proteins are packaged into vesicles.     

Analysis of a processing system for proteases using yeast cell surface engineering: conversion of precursor of proteinase A to active proteinase A

The display of a protease, carboxypeptidase Y (CPY) or procarboxypeptidase Y (proCPY), which is the vacuolar protease, on the yeast-cell surface was successfully performed using yeast-cell-surface engineering for the first time. Through that we could confirm the processing of vacuolar proteases containing proteinase A (PrA) and proteinase B (PrB) which are related to the maturation of proCPY, using a novel cell-surface engineering technique. Various protease-knockout strains of Saccharomyces cerevisiae with the CPY-displaying system were constructed to evaluate the operation of the activation process of CPY. The display of CPY (CPY-agg, which is a fusion protein of CPY with C-terminal half of α-agglutinin) on the cell surface was confirmed by immunofluorescence staining. The activity of the CPY-agg was determined after the conversion of proCPY to active CPY by treatment of whole cells with proteinase K. In the proCPY-displaying CPY-knockout strain and PrB-knockout strain, CPY was displayed as an active (mature) form, but in the proCPY-displaying PrA-knockout strain, CPY was present as an inactive form (proCPY). These facts indicate that PrA had been already activated before its transport to the vacuole and that active mature PrA might convert proCPY to CPY before the transport of proCPY to the vacuole. From these results, it was suggested that by using the yeast-cell-surface engineering at the location of the initial step, the autocatalytic activation from proPrA to PrA might occur before the vacuolar branch separates from the main secretory pathway.     

Identification of interaction site of propeptide toward mature carboxypeptidase Y (mCPY) based on the similarity between propeptide and CPY inhibitor (IC)

Both the propeptide in the precursor carboxypeptidase Y (proCPY) and the mature CPY (mCPY)-specific endogenous inhibitor (I(C)) inhibit CPY activity. The N-terminal inhibitory reactive site of I(C) (the N-terminal seven amino acids of I(C)) binds to the substrate-binding site of mCPY and is essential for mCPY inhibition, but the mechanism of mCPY inhibition by the propeptide is poorly understood. In this study, sequence alignment between I(C) and proCPY indicated that a sequence similar to the N-terminal region of I(C) was present in proCPY. In particular, a region including the C-terminus of the propeptide was similar to the N-terminal seven amino acids of I(C). In the presence of peptides identical to the N-terminus of I(C) and the C-terminus of the propeptide, CPY activity was competitively inhibited. The C-terminal region of the propeptide might bind to the substrate-binding site of mCPY.     

vac2: a yeast mutant which distinguishes vacuole segregation from Golgi-to-vacuole protein targeting.

We have isolated four yeast mutants that are unable to partition maternal vacuoles into growing buds. Three of these vacuole segregation (vac) mutants also mislocalize the vacuolar protease carboxypeptidase Y (CPY) to the cell surface, a phenotype previously reported for vac strains. A fourth mutant, vac2-1, exhibits a temperature-sensitive defect in vacuole segregation but does not show a defect in protein targeting from the Golgi apparatus to the vacuole. Haploid vac2-1 cells grown at the non-permissive temperature do not secrete CPY or a second vacuolar protease, proteinase A (PrA). Furthermore, newly synthesized precursors of CPY are converted to mature forms with similar kinetics in both vac2-1 and wild-type cells. In addition, invertase is secreted normally from vac2-1 cells, indicating that post-Golgi steps in the secretory pathway are not blocked in this mutant. These results suggest that VAC2 function is necessary for vacuole division and segregation in yeast but is not involved in vacuole protein sorting events at the Golgi apparatus.     

Distinct sequence determinants direct intracellular sorting and modification of a yeast vacuolar protease

We have mapped a sequence determinant in the vacuolar glycoprotein carboxypeptidase Y (CPY) that directs intracellular sorting of this enzyme. Through the study of hybrid proteins, consisting of amino-terminal segments of CPY fused to the secretory enzyme invertase, we have found that the N-terminal 50 amino acids of CPY are sufficient to direct delivery of a CPY-Inv hybrid protein to the yeast vacuole. Our data suggest that this 50 amino acid segment of CPY contains two distinct functional domains; an N-terminal signal peptide followed by a segment of 30 amino acids that contains the vacuolar sorting signal. Deletion of this putative vacuole sorting signal from an otherwise wild-type CPY protein leads to missorting of CPY. Furthermore, examination of the Asn-linked oligosaccharides present on CPY and CPY-Inv hybrid proteins suggests that an additional determinant in CPY specifies the extent to which these proteins are glycosylated in the Golgi complex.     

Alternative pathways for the sorting of soluble vacuolar proteins in yeast: a vps35 null mutant missorts and secretes only a subset of vacuolar hydrolases.

vps35 mutants of Saccharomyces cerevisiae exhibit severe defects in the localization of carboxypeptidase Y, a soluble vacuolar hydrolase. We have cloned the wild-type VPS35 gene by complementation of the vacuolar protein sorting defect exhibited by the vps35-17 mutant. Sequence analysis revealed an open reading frame predicted to encode a protein of 937 amino acids that lacks any obvious hydrophobic domains. Subcellular fractionation studies indicated that 80% of Vps35p peripherally associates with a membranous particulate cell fraction. The association of Vps35p with this fraction appears to be saturable; when overproduced, the vast majority of Vps35p remains in a soluble fraction. Disruption of the VPS35 gene demonstrated that it is not essential for yeast cell growth. However, the null allele of VPS35 results in a differential defect in the sorting of vacuolar carboxypeptidase Y (CPY), proteinase A (PrA), proteinase B (PrB), and alkaline phosphatase (ALP). proCPY was quantitatively missorted and secreted by delta vps35 cells, whereas almost all of proPrA, proPrB, and proALP were retained within the cell and converted to their mature forms, indicating delivery to the vacuole. Based on these observations, we propose that alternative pathways exist for the sorting and/or delivery of proteins to the vacuole.     

Mutated intramolecular chaperones generate high-activity isomers of mature enzymes

The propeptide of carboxypeptidase Y precursor (proCPY) acts as an intramolecular chaperone that ensures the correct folding of the mature CPY (mCPY). Here, to further characterize the folding mechanism mediated by the propeptide, folding analysis was performed using a yeast molecular display system. CPYs with mutated propeptides were successfully displayed on yeast cell surface, and the mature enzymes were purified by the selective cleavage of mutated propeptides. Measurement of the activity and kinetics of the displayed CPYs indicated that the propeptide mutation altered the catalytic efficiency of mCPY. Although the mature region of the wild-type and mutant CPYs had identical amino acid sequences, the mCPYs from the mutant proCPYs had higher catalytic efficiency than the wild-type. These results indicate that proteins with identical amino acid sequence can fold into isomeric proteins with conformational microchanges through mutated intramolecular chaperones.     

Membrane protein sorting: biosynthesis, transport and processing of yeast vacuolar alkaline phosphatase.

The Saccharomyces cerevisiae PHO8 gene product, repressible alkaline phosphatase (ALP), is a glycoprotein enzyme that is localized to the yeast vacuole (lysosome). Using antibodies raised against synthetic peptides corresponding to two distinct hydrophilic sequences in ALP, we have been able to examine the biosynthesis, sorting and processing of this protein. ALP is synthesized as an inactive precursor containing a C-terminal propeptide that is cleaved from the protein in a PEP4-dependent manner. The precursor and mature protein are anchored in the membrane by an N-terminal hydrophobic domain that also appears to function as an uncleaved internal signal sequence. ALP has the topology of a type-II integral membrane protein containing a short basic N-terminal cytoplasmic tail that is accessible to exogenous protease when associated both with the endoplasmic reticulum and the vacuole. Similar to the soluble vacuolar hydrolases carboxypeptidase Y (CPY) and proteinase A (PrA), ALP transits through the early stages of the secretory pathway prior to vacuolar delivery. Two observations indicate, however, that ALP is localized to the vacuole by a mechanism which is in part different from that used by CPY and PrA: (i) maturation of proALP, which is indicative of vacuolar delivery, is less sensitive than CPY and PrA to the defects exhibited by certain of the vacuolar protein sorting (vps) mutants; and (ii) maturation of proALP proceeds normally in the presence of a potent vacuolar ATPase inhibitor, bafilomycin A1, which is known to block vacuole acidification and leads to the mis-sorting and secretion of precursor forms of CPY and PrA. These results indicate that ALP will be a useful model protein for studies of membrane protein sorting in yeast.     

Identification and characterization of a prevacuolar compartment in stigmas of nicotiana alata

The stigmas of the ornamental tobacco plant Nicotiana alata accumulate large quantities of a series of 6-kD proteinase inhibitors (PIs) in the central vacuole that are derived from a 40-kD precursor protein, Na-PI. The sorting information that directs Na-PI to the vacuole is likely to reside in a C-terminal propeptide domain of 25 amino acids that forms an amphipathic alpha helix. Using cell fractionation techniques, we have examined transit of Na-PI through the endomembrane system and have identified a prevacuolar compartment that contains Na-PI with an intact targeting signal. In contrast, the targeting signal is not present on the predominant form of Na-PI in the vacuole. The prevacuolar compartment is marked by the presence of homologs of both the t-SNARE, PEP12p, and the putative vacuolar sorting receptor BP-80. Cross-linking and affinity precipitation studies revealed that Na-PI associates with BP-80 within this compartment, providing in vivo evidence for the function of BP-80 as a sorting receptor for a protein with a C-terminal vacuolar targeting signal.     

Yeast vacuolar proenzymes are sorted in the late Golgi complex and transported to the vacuole via a prevacuolar endosome-like compartment

We are studying intercompartmental protein transport to the yeast lysosome-like vacuole with a reconstitution assay using permeabilized spheroplasts that measures, in an ATP and cytosol dependent reaction, vacuolar delivery and proteolytic maturation of the Golgi-modified precursor forms of vacuolar hydrolases like carboxypeptidase Y (CPY). To identify the potential donor compartment in this assay, we used subcellular fractionation procedures that have uncovered a novel membrane-enclosed prevacuolar transport intermediate. Differential centrifugation was used to separate permeabilized spheroplasts into 15K and 150K g membrane pellets. Centrifugation of these pellets to equilibrium on sucrose density gradients separated vacuolar and Golgi complex marker enzymes into light and dense fractions, respectively. When the Golgi-modified precursor form of CPY (p2CPY) was examined (after a 5-min pulse, 30-s chase), as much as 30-40% fractionated with an intermediate density between both the vacuole and the Golgi complex. Pulse-chase labeling and fractionation of membranes indicated that p2CPY in this gradient region had already passed through the Golgi complex, which kinetically ordered it between the Golgi and the vacuole. A mutant CPY protein that lacks a functional vacuolar sorting signal was detected in Golgi fractions but not in the intermediate compartment indicating that this corresponds to a post-sorting compartment. Based on the low transport efficiency of the mutant CPY protein in vitro (decreased by sevenfold), this intermediate organelle most likely represents the donor compartment in our reconstitution assay. This organelle is not likely to be a transport vesicle intermediate because EM analysis indicates enrichment of 250-400 nm compartments and internalization of surface-bound 35S-alpha-factor at 15 degrees C resulted in its apparent cofractionation with wild-type p2CPY, indicating an endosome-like compartment (Singer, B., and H. Reizman. 1990. J. Cell Biol. 110:1911-1922). Fractionation of p2CPY accumulated in the temperature sensitive vps15 mutant revealed that the vps15 transport block did not occur in the endosome-like compartment but rather in the late Golgi complex, presumably the site of CPY sorting. Therefore, as seen in mammalian cells, yeast CPY is sorted away from secretory proteins in the late Golgi and transits to the vacuole via a distinct endosome-like intermediate.     

Determination of the functional elements within the vacuolar targeting signal of barley lectin.

We have previously demonstrated that the carboxyl-terminal propeptide of barley lectin is both necessary and sufficient for protein sorting to the plant vacuole. Specific mutations were constructed to determine which amino acid residues or secondary structural determinants of the carboxyl-terminal propeptide affect proper protein sorting. We have found that no consensus sequence or common structural determinants are required for proper sorting of barley lectin to the vacuole. However, our analysis demonstrated the importance of hydrophobic residues in vacuolar targeting. In addition, at least three exposed amino acid residues are necessary for efficient sorting. Sorting was disrupted by the addition of two glycine residues at the carboxyl-terminal end of the targeting signal or by the translocation of the glycan to the carboxy terminus of the propeptide. These results suggest that some components of the sorting apparatus interact with the carboxy terminus of the propeptide.     

Vps10p cycles between the TGN and the late endosome via the plasma membrane in clathrin mutants

Clathrin-coated vesicles mediate the transport of the soluble vacuolar protein CPY from the TGN to the endosomal/prevacuolar compartment. Surprisingly, CPY sorting is not affected in clathrin deletion mutant cells. Here, we have investigated the clathrin-independent pathway that allows CPY transport to the vacuole. We find that CPY transport is mediated by the endosome and requires normal trafficking of its sorting receptor, Vps10p, the steady state distribution of which is not altered in chc1 cells. In contrast, Vps10p accumulates at the cell surface in a chc1/end3 double mutant, suggesting that Vps10p is rerouted to the cell surface in the absence of clathrin. We used a chimeric protein containing the first 50 amino acids of CPY fused to a green fluorescent protein (CPY-GFP) to mimic CPY transport in chc1. In the absence of clathrin, CPY-GFP resides in the lumen of the vacuole as in wild-type cells. However, in chc1/sec6 double mutants, CPY-GFP is present in internal structures, possibly endosomal membranes, that do not colocalize with the vacuole. We propose that Vps10p must be transported to and retrieved from the plasma membrane to mediate CPY sorting to the vacuole in the absence of clathrin-coated vesicles. In this circumstance, precursor CPY may be captured by retrieved Vps10p in an early or late endosome, rather than as it normally is in the trans-Golgi, and delivered to the vacuole by the normal VPS gene-dependent process. Once relieved of cargo protein, Vps10p would be recycled to the trans-Golgi and then to the cell surface for further rounds of sorting.     

Protein transport to the vacuole and receptor-mediated endocytosis by clathrin heavy chain-deficient yeast

Clathrin heavy chain-deficient mutants (chcl) of Saccharomyces cerevisiae are viable but exhibit compromised growth rates. To investigate the role of clathrin in intercompartmental protein transport, two pathways have been monitored in chcl cells: transport of newly synthesized vacuolar proteins to the vacuole and receptor-mediated uptake of mating pheromone. Newly synthesized precursors of the vacuolar protease carboxypeptidase Y (CPY) were converted to mature CPY with similar kinetics in mutant and wild-type cells. chcl cells did not aberrantly secrete CPY and immunolocalization techniques revealed most of the CPY in chcl cells within morphologically identifiable vacuolar structures. Receptor-mediated internalization of the mating pheromone alpha-factor occurred in chcl cells at 36-50% wild-type levels. The mutant cells were fully competent to respond to pheromone-induced cell-cycle arrest. These results argue that in yeast, clathrin may not play an essential role either in vacuolar protein sorting and delivery or in receptor-mediated endocytosis of alpha-factor. Alternative mechanisms ordinarily may execute these pathways, or be activated in clathrin-deficient cells.     

Colocalization of barley lectin and sporamin in vacuoles of transgenic tobacco plants.

Various targeting motifs have been identified for plant proteins delivered to the vacuole. For barley (Hordeum vulgare) lectin, a typical Gramineae lectin and defense-related protein, the vacuolar information is contained in a carboxyl-terminal propeptide. In contrast, the vacuolar targeting information of sporamin, a storage protein from the tuberous roots of the sweet potato (Ipomoea batatas), is encoded in an amino-terminal propeptide. Both proteins were expressed simultaneously in transgenic tobacco plants to enable analysis of their posttranslational processing and subcellular localization by pulse-chase labeling and electron-microscopic immunocytochemical methods. The pulse-chase experiments demonstrated that processing and delivery to the vacuole are not impaired by the simultaneous expression of barley lectin and sporamin. Both proteins were targeted quantitatively to the vacuole, indicating that the carboxyl-terminal and amino-terminal propeptides are equally recognized by the vacuolar protein-sorting machinery. Double-labeling experiments showed that barley lectin and sporamin accumulate in the same vacuole of transgenic tobacco (Nicotiana tabacum) leaf and root cells.     

Yeast carboxypeptidase Y requires glycosylation for efficient intracellular transport, but not for vacuolar sorting, in vivo stability, or activity

Functions of the carbohydrate side chains of the yeast vacuolar enzyme carboxypeptidase Y (CPY) were investigated by removal, through site-directed mutagenesis, of the sequences which act as signals for N-linked glycosylation. The mutant forms of the enzyme were analysed with respect to activity and intracellular sorting, and the stabilities in vivo and in vitro were studied. It was found that carbohydrate was not important for accurate vacuolar targeting of CPY, but that the rate of transport of the unglycosylated CPY through the secretory pathway to the vacuole was reduced. Tunicamycin, which inhibits the formation of asparagine-linked glycosylation, had a similar effect on the transport of CPY at 23 degrees C. However, the absence of N-linked carbohydrate in general had the more dramatic result of blocking the transport of CPY altogether at an increased temperature (37 degrees C). The unglycosylated mutant CPY was not temperature sensitive for transport in the absence of tunicamycin. Analysis of mutant enzymes containing a single glycosyl residue at each of the four positions showed that the residue at position 87 was particularly important for transport. There was no decrease in the intracellular stability of the completely unglycosylated enzyme, and in vitro the rate of heat inactivation of this species was not increased.     

Yeast carboxypeptidase Y can be translocated and glycosylated without its amino-terminal signal sequence

We have constructed a series of mutations in the signal sequence of the yeast vacuolar protein carboxypeptidase Y (CPY), and have used pulse-chase radiolabeling and immunoprecipitation to examine the in vivo effects of these mutations on the entry of the mutant CPY proteins into the secretory pathway. We find that introduction of a negatively charged residue, aspartate, into the hydrophobic core of the signal sequence has no apparent effect on signal sequence function. In contrast, internal in-frame deletions within the signal sequence cause CPY to be synthesized as unglycosylated precursors. These are slowly and inefficiently converted to glycosylated precursors that are indistinguishable from the glycosylated forms produced from the wild-type gene. These precursors are converted to active CPY in a PEP4-dependent manner, indicating that they are correctly localized to the vacuole. Surprisingly, a deletion mutation that removes the entire CPY signal sequence has a similar effect: unglycosylated precursor accumulates in cells carrying this mutant gene, and greater than 10% of it is posttranslationally glycosylated. Thus, the amino-terminal signal sequence of CPY, while important for translocation efficiency, is not absolutely required for the translocation of this protein.     

Isolation and characterization of yeast mutants in the cytoplasm to vacuole protein targeting pathway

In Saccharomyces cerevisiae the vacuolar protein aminopeptidase I (API) is localized to the vacuole independent of the secretory pathway. The alternate targeting mechanism used by this protein has not been characterized. API is synthesized as a 61-kD soluble cytosolic precursor. Upon delivery to the vacuole, the amino-terminal propeptide is removed by proteinase B (PrB) to yield the mature 50-kD hydrolase. We exploited this delivery-dependent maturation event in a mutant screen to identify genes whose products are involved in API targeting. Using antiserum to the API propeptide, we isolated mutants that accumulate precursor API. These mutants, designated cvt, fall into eight complementation groups, five of which define novel genes. These five complementation groups exhibit a specific defect in maturation of API, but do not have a significant effect on vacuolar protein targeting through the secretory pathway. Localization studies show that precursor API accumulates outside of the vacuole in all five groups, indicating that they are blocked in API targeting and/or translocation. Future analysis of these gene products will provide information about the subcellular components involved in this alternate mechanism of vacuolar protein localization.     

Morphological classification of the yeast vacuolar protein sorting mutants: evidence for a prevacuolar compartment in class E vps mutants.

The collection of vacuolar protein sorting mutants (vps mutants) in Saccharomyces cerevisiae comprises of 41 complementation groups. The vacuoles in these mutant strains were examined using immunofluorescence microscopy. Most of the vps mutants were found to possess vacuolar morphologies that differed significantly from wild-type vacuoles. Furthermore, mutants representing independent vps complementation groups were found to share aberrant morphological features. Six distinct classes of vacuolar morphology were observed. Mutants from eight vps complementation groups were defective both for vacuolar segregation from mother cells into developing buds and for acidification of the vacuole. Another group of mutants, represented by 13 complementation groups, accumulated a novel organelle distinct from the vacuole that contained a late-Golgi protein, active vacuolar H(+)-ATPase complex, and soluble vacuolar hydrolases. We suggest that this organelle may represent an exaggerated endosome-like compartment. None of the vps mutants appeared to mislocalize significant amounts of the vacuolar membrane protein alkaline phosphatase. Quantitative immunoprecipitations of the soluble vacuolar hydrolase carboxypeptidase Y (CPY) were performed to determine the extent of the sorting defect in each vps mutant. A good correlation between morphological phenotype and the extent of the CPY sorting defect was observed.     

Identification of a cytoplasm to vacuole targeting determinant in aminopeptidase I

Aminopeptidase I (API) is a soluble leucine aminopeptidase resident in the yeast vacuole (Frey, J., and K.H. Rohm. 1978. Biochim. Biophys. Acta. 527:31-41). The precursor form of API contains an amino-terminal 45-amino acid propeptide, which is removed by proteinase B (PrB) upon entry into the vacuole. The propeptide of API lacks a consensus signal sequence and it has been demonstrated that vacuolar localization of API is independent of the secretory pathway (Klionsky, D.J., R. Cueva, and D.S. Yaver. 1992. J. Cell Biol. 119:287-299). The predicted secondary structure for the API propeptide is composed of an amphipathic alpha- helix followed by a beta-turn and another alpha-helix, forming a helix- turn-helix structure. With the use of mutational analysis, we determined that the API propeptide is essential for proper transport into the vacuole. Deletion of the entire propeptide from the API molecule resulted in accumulation of a mature-sized protein in the cytosol. A more detailed examination using random mutagenesis and a series of smaller deletions throughout the propeptide revealed that API localization is severely affected by alterations within the predicted first alpha-helix. In vitro studies indicate that mutations in this predicted helix prevent productive binding interactions from taking place. In contrast, vacuolar import is relatively insensitive to alterations in the second predicted helix of the propeptide. Examination of API folding revealed that mutations that affect entry into the vacuole did not affect the structure of API. These data indicate that the API propeptide serves as a vacuolar targeting determinant at a critical step along the cytoplasm to vacuole targeting pathway.